Tabulating machine



Jan. 5, 1937.

c. CAMPBELL I TABULATING MACHINE Filed Oct. 27, 1931 F IG.1.

6 Sheets-Sheet l I I l glNVvENTORL MM' 'ATTORNEY- l Jan. 5, 1937.

c. CAMPBELL l e 2,066,764 TABULATING MACHINE Filed Oct. 27, 1931 figc@ 6 Sheets-Sheet 2 ZO he E www? y mfr/70 ATTORNEY.-

Jan. 5, 1937. f x i c. CAMPBELL 2,066,764

TABULATING MACHINE Filed Oct.` 27, 1951 6 Sheets-Sheet 31 Pisa.

ATTORNEY- Jan. '5, 1937. c. CAMPBELL l 2,066,764

TABULATING MACHINE Filed Oct. 27, 1931 6 Sheets-Sheet 4 Plas. y Fm., i;

'ATTORNEY- Jan, 5, 1937. c.`cAMPBEL| 2,066,764

TBULATING MACHINE Filed, oct. 27, 1931 6 sheets-'sheet 5 FIGB.

INVENTOR--I BAY/4% ArToRNEY- Jan. 5,1937. l c. CAMPBELL l 2,066,764

TABULATING MAcrINE Filed oct. 27, 1951 e Sheng-sheet e /IZO rzl ,z5 f m22 l l v El iq i.;

127; l f l A W3 o 2 a 4 5 6 7 a 9 v 'v i INVENTOR- V BY l Patented `lan. 5, l 1937 UNITED STATES PATENT oFFicE TABULATING MACHINE Charles Campbell, London, England, assigner, by

- mesne assignments, to International Business f Machines Corporation, New York, N. Y., a corporation of New York I Application October 27, 1931, Serial No. 571,331.-

In Great Britain July 2, 1931 6 Claims.

I expressed in the British or Indian currency or Weights according to the British system. l

For the sake of simplicity the problem vWith which the present invention is concerned will be explained in connection with adding mechanism but the invention is applicable to other calculating mechanisms. i`r:a.ctions may be handled in adding mechanism by providing a denominational adding element operating according to a notation the base of which is the denominator of the fractions, the numerators of the fractions being en-- tered into the adding element. Thus eighths can be handled in an adding element operating according to the eighths notation, that is on an eight-point cycle. It is not, however, convenient,.

for various reasons, to employ an adding element operating in accordance with a notation of a higher base than ten, although pence have been dealt with in this way, and the vdifficulty involved in so operating an addingfelement increases With-base of the notation. It is the practice to split such fractions into two fractions the denominators of which areless than ten. Thus sixteenths would be treated as halves and eighths of halves and enter-ed into a halves adding element operating in the two notations and the eighths adding element operating on the eighths notation and transferring to the rst adding element. If seven sixteenths is to be entered, seven should be entered into the eighths adding element While lif thirteen sixteenths is to be added, one should be enteredinto the halves adding element and ve into the eighths adding element. Hithertoit has been necessary to enter and print or otherwise record the amounts in the notation suitable for adding mechanism. Thus thirteen sixteenths would be entered and recorded as 15 which is inconvenient.

It is the object of this invention to provide means whereby an amount expressed in one notation may be converted into the terms of another notation appropriate to the device into which it is to be entered. Accordingly, the invention provides the combination with an entering device and a receiving device operating 'according to different notations, of translating mechanism arranged to receive from the entering device an amountexpressed in the notation appropriate to that device, to convert it into the terms of the notation appropriate to the receiving device and to transmit the converted amount to the receiving device. The phrase entering device is intended to cover not merely the record reading device controlling the machine, but also, where the context so permits, any device from Cil whichl amounts are transferred to a receiving d`evice. 'I'hus the entering device could be an adding or other calculating'mechanism and the receiving device a printing mechanism.

"According to another feature of the invention, there is provided a statistical, calculating or like machine comprising in combination a primary entering device operable in "accordance with a normal notation, an adding mechanism, operable in accordance With a special notation and a translating mechanism automatically operable to receive amounts from the entering device, to convert them from the normal notation into the special notation and to enter the converted amounts to the adding mechanism.

In order to permit of amounts entered being subtracted, the translating mechanism may also be operable to obtain the complements of the converted amounts and selecting mechanism maybe provided for determining whether the converted amount or its complement is transmitted to the adding mechanism in accordance with whether .the entered amount is to be added`v or subtracted'.

When the machine includes mechanism for recording a total standing on the adding mechanism it is desirable that this total should be recorded in the normal notation. For this purpose a second translator may be provided which is automatically operable to reconvert the total standing in the adding mechanism into the terms of the normal notation and to control the recording of the reconverted amount by the recording mechanism. In order to allow of the recordingyof the amounts entered, an operative connection mayA lreceiving device.

a unitsdigit and a tens digit respectively to the When the receiving device is 0f the kind whose operation depends on the time of its cycle of operations at which a controlling impulse is received by it, the units of each portion of the translating mechanism may be operable in synchronism with the receiving device, adjustable in accordance with the digit entered in its denomination to transmit an impulse to the receiving device at a unique time in its own cycle of operation andA include means whereby the phase relationship between it and the receivingl device is varied automatically in accordance with the digit entered in the other denomination.

.Two embodiments of the present invention as applied to a record-card-controlled statistical ,I machine will now be described, by way of example the machine and is taken on the line 4-4 of Fig. 5.

Fig. 5 is a section on the line 5 5 of Fig. 4.

Fig. 6 is an elevation of one translating unit employed in the machine.

Fig.,6a is a detail of the latching devices shown in Fig. .6. Fig. 7 is an end-elevation of Fig. 6.

Figs. 8 and 9 taken together form a circuit diagram for translating mechanism arranged to deal with twenty-eighths.

Like reference numerals indicate like parts in all the figures of the drawings.

The invention will be described as applied to a machine of the kind shown in the patent to G. F, Daly et al. No. 1,762,145, issued June 10, 1930. As this kind of machine is well known it will only bedescribed sufficiently for an understanding of the present invention and reference should be made to the above mentioned patent for a more .detailed description.

General arrangement 'I'he machine which will now be 'described is arranged to add and subtract amounts expressed in terms of the Indian currency, that is in rupees and annas. Before describing the manner in which the annas or sixteenths of a rupee are dealt with a. general description of the machine and the manner in which it handles rupees will be given. 'I'he rupees are decimal amounts and are dealt with in the usual manner by means of decimal adding and printing mechanism.

The machine is controlled by Hollerith cards in which each digit'is represented by the position or a hole in a column of ten index point-s or hole positions in a known manner. The machine is driven during card feeding operations by a tabulating motor, not show n, and during total printing and resetting operations by a reset motor RM (Fig. 1).

'Ihe tabulating lmotor drives card feeding mechanism of a conventional kind which feeds veach card between a contact roll I II (Fig. 2) and upper brushes UB and then past lower brushes LBand a contact roll II. Each card passes the lower brushes in synchronism with'fthe passage of the succeeding card past the upper brushes.

gear wheel com-es to rest.

" as is showninFig. 1.

'I'he tabulating motor also drives a v.shaft I2 (Fig. 4) through suitable gearing and this shaft drives the accumulator or adding mechanism of the machine. A plurality of gear wheels I3 are loosely mounted on the'shaft I2 and are provided each with one half of a clutch I4, the other half of which is splined on thev shaft I2. I4 is normally held disengaged by mechanism I5 in the usual manner. The mechanism I 5 is controlled by an electromagnet I6 which when energized causes thev mechanismv I5 to engage the clutch. The gear wheel I3 then turns with the shaft l2 until the zero time in the cycle of the machine when the clutch is demeshed and the The magnet I6 (Fig. 2) is energized over a circuit extending from a main supply line I'I through `cam contacts CFI, lower card lever contacts LCLC which are closed so long as cards are feeding past the lower brushes, a line I9, the contact roll II., a lower brush LB, a plug connection 20, a line 2|, a pair of normally closed contacts 22a, a plug connection 23, the magnet I6 and a pair of contacts 24 to another supply line 25. This circuit will be established at a time determined by the position of a hole in the column read by the brush LB and.

the corresponding gear wheel I3 will begin to turn. Since the cards are fed with the nine holes leading, the gear wheel will turn to an extent which is proportional to the value of the digit represented by the hole before it is disconnected at the zero time in the cycle. Each gear wheel I3 meshes with a gear wheel 26 which is secured to a counter wheel 21 loos-ely mounted on a shaft The counter wheels 21 are arranged to turn through a complete revolution for an. entry of 10 while the shaft I2 turns through a complete revolution per machine cycle and through a ten-fourteenths of a revolution during the time required to enter 10.. The gear ratio between Wheels 26 `and I3 is therefore 10 to 14. The gears are not shown in this ratio in Fig. 4. 'I'he ratio shown is t that in the units order of the accumulator; i. e., the order in which annas are to be entered. The

The clutch reason for the ratio so shown will be hereinafter .is not shown and may be of any convenient form.

Further detailed explanation of this well known accumulating mechanism and its transfer devices may be found in the Patent #1,307,740, issued June 24, 1919 to C. D. Lake.

'I'he amounts added in this manner may also be printed by means of printing mechanism such The typebar 220 is positioned relatively to the platen 22| to'bring the proper type 222 into/.printing position opposite the platen. The total taking shaft 223 driven by the reset motor RM is provided with a cam '224 cooperating with a roller 225 carried on arm '226 freely rotatable on shaft 221.

As the cam rotates, arm 226 rocks clockwise and a-lug 228` cooperating with an arm 229 fixed to shaft 221 also rocks clockwise. An'arm 230 fixed to shaft 221 is linked to printing crosshead 23| which serves to raise the type bar 220 in synchronism with the total taking operation so that the type 222 successively pass printing position opposite platen 22|. Owing to spring operated scissors connections 232, however, the type bar may be arrested in any printing position without inter- The printing magnets 29 (Fig. 2) may be enerl gized from circuits extending through the lower brushes and wires' 30 to the printing magnets. When thus energized each printing magnet arrests a type bar in a position to print a digit. The time at which each magnet is energized is determined by the position of the controlling hole in the card and in turn determines the digit which the corresponding type bar will be positioned to print.

The amounts read from the cards may be subtractedinstead of being added. Subtraction is ,effected in a known manner by entering the complement of the amount read from the card into the adding mechanism. The complement is obtained by means of a translator of the kind described in British patent specication No. 288,516. This mechanism is illustrated in Figs. 6 and 7. As each card passes the upper brush a circuit is established from the line l1 throughcontacts CF2 which are operated during card feeding cycles only, cardlever contacts UCLC closed so long as cards are passing the' upper brushes, normally lclosed contacts 3| and a translator magnet 32 to the other main line 25. The magnet 32 when thus energized attracts its armature 33 which normally latches a spring-pressed trip latch 34. The trip latch moves upwardly to the upper dotted line position as shown and p-ermits a rod 35 to move to the right and to allow the contacts 3| to open and interrupt the circuit of the magnet 32. A disk 36 of insulated material is mounted on a shaft 31 which is driven a commutator segment 43 (see also Fig. 2) which by the tabulating motor and carries ltwo-sector-v shaped metal plates 38. The shaft 31 makes one trevolution fortwo card cyclesso that one of the plates 38 is moved past they trip lever 34 during one cycle and the other plate during the other cycle.

pawl 4| (see Fig. 6a) the other end of which projects from the disk so as to miss the hooked end of the trip lever when the`lattcr is in latched position but to engage it when it is unlatched as described above.

The spring contact blades cooperate with individual contacts 42 mounted on the disk 36 and passing through openings in the plates 33 so that when the magnet 32 is energized the trip lever 34 rocks one of the trip pawls 4| which unlatches its plunger 40 s6 that the corresegments pass under a brush 44' in synchronism with the cycle ofthe machine. As shown in Figs.

Each plate 38 carries a series of spring y blades 39 each of which is held open by a plunger 40 which is engaged by one end of a pivoted trip 2 and 6 the contacts 42 are cross-connected to the segments 43, so that the leading contact 42 y is connected to the trailing segment 43 and sov on. All the contact blades 39 are connected tov a common segment 45 which is read by a brush 46. The translator is in duplicate so .that one half may be set up by the magnet 32 during one card cycle while the other half which was set up during the preceding card cycle is being read by the brushes 44 and 46. For the sake of simplicity only one half of the translator *is show in Fig. 2. -Assuming that 8 is read by t e brushes, the second pair of contacts from the right in Fig. 2 will be closed during one card y cycle. During the next card cycle when the card in question has reached the lower brushes a circuit will be set up from the line I1 through the contacts CFI, the lower card lever contacts, a line 41, brush 46, the segment 45, the closed contacts 39 and 42 which correspond to the digit 8, the second segment 43 from the left and the brush 44 to a line 48. Since the segments 43 pass the brush 44 in synchronism with the machine cycle, this circuit is established at the one time of the cycle, that is at this time corresponding to the complement with respect to 9 of the entered digit.

If contacts 22h are closed, the circuit will continue through the plug wire 23, and adding magnets I6 and the contacts 24 to the line 25. The contacts 22a and 22h are controlled by a magnet 22 (Fig. 2) which is energized whenever a hole is read in the so-called X position of a column of the record card. This hole denotes that the amount on that card is to be subtracted and when it is read a circuit is established from the line |1 through the contacts CFZ and UCLC, the contact roll I0, an upper brush UB4, cam

lcontacts X, timed to close only while the X hole positions are passing the brushes, a holding relay coil 49 and the magnet 22 to the other `main line 25. 'I'he holding coil 49 then closes its contacts 49a and establishes a holding circuit for itself and the magnet 22 through, cam contacts CF3. These contacts are closed except for a short period after the zero time in each card cycle. Thus, when an X hole is read these contacts are closed and they will remain closed during the whole of the entering. portion of the next cycle. Whenv energized the magnet '22 opens A yits contacts 22a and closes its contacts 22h connecting the corresponding adding magnet I6 to the brush 44 of the translator and disconnecting it from the lower brushes so that the ccmplement of the amount on the card will be entered from the translator instead of the amount read by the lower brushes.

The machine is provided with the usual control circuits which maintain the tabulating motorv in operation so long as the cards read by the upper brushes belong to the same group as the card passing the lower brush. This mechanism compares the holes representing the group number on the card passing the lower brushes with the corresponding holes on the card passing the upper brush and interrupts the operation of the tabulating motor as soon as these holes disagree.

The interruption of the operation of the tabulating motor results in the card feeding mechanism ceasing to operate and the accumulators not being driven. Simultaneously the energizing circuit for the reset motor is completed automatically and the machine goes through a total print and resetting cycle. The totals are printed dur- Cil ing the rst half or this cycle in themanner which will be explained below and the accumulator is reset during the second half of the cycle in the known manner. Theresetting. motor is arranged to drive the printing mechanism so that totals may 'be printed and also certain total timing commutators or impulse emitters which will be described later. The control circuits are fully described in the Patent 1,762,145 aforesaid and have not been shown in the drawings.

The machine is provided with mechanism for reading out totals standing on the accumulator.

to the printing mechanism, which reading out mechanism will now be described.

'I'he gear wheels I3 (Fig. 5)r for the decimal adding Wheels 21 mesh with gear Wheels 50 which are' loosely mounted on a shaft 5I. Each Wheel 50 has an insulating disk 52 secured to it and a mutators is shown at the bottom of Fig. 2 and it will be seen that the brushes 53 connect one of the segments 55 to the segment 54 in .accordance with the Value standing in that denominator of the accumulator. Like conducting segments 55 are connected together by bus-bars 51 which are connected each to a separate one of ten segments 6I on an emitting commutator 58.

The emitting commutator has a common segment 59 and a pair of brushes 60 which are driv-` en in synchronism' with the machine cycle.to connect each segment 6I in\turn to the segment 59. The arrangement isksuch that the segment 6I which is engaged by a brush 6I) at the nine time in the cycle is connected to all the seg- 'ments 55 which are engaged by a brush 53 when the corresponding adding wlieel standslat 9 and S0 On. l

The brush 60 is driven by the reset motor and,

vWhen a total print and reset operation is initiated, a circuit will b' established .from the line I1, through star cam contacts RI which are operated during reset cycles only, the segment 59, brush 60, one of the segments 6I, the correspondingbus line 51 to the corresponding segment 55 of oneof the read-out commutators, the brush 53, the segment 54, a plug wire 62, a line 63, and the corresponding print magnet 29, to the other supplyl line 425. The time at which this circuit is established depends'on the position of the brush 53 and corresponds to the digit represented by `the position of this brush so that the amount standing in this denomination of ,fthe accumulator will be printed.

The above has explained how decimal portions voi? the amounts, that is, amounts entered in all orders but the units-and tens orders, may be added or subtracted and the total printed. This has been explained in connection with Fig. 4

nsl

which shows the .arrangement of parts in the units order but itl will'be understood that the higher orders differ frmFig. 4 only in the ratio of the gearing 26, I3 and 50 or 50a. The manner in. which non-decimal portions oftheA amounts are entered will now be explained.

Y subtracting the converted amount.

Entering siteenths The systemV in accordance with which sixteenths are handled isrshown in Table I below:

i i Table I i r l lilgh Listing J.adding Sutizact Total print 00 17 01 1 01 16 l 02 2 02 15 2 03 3 03 14 3 04 4 04 13 4 05 5 05 12 5 06 6 06 11 6 07 7 07 10 7 08 8 10 07 8` 09 9 1l 06 9 10 10 12 05 10 11 ii 13 o4 11 12 12 14 03 12 13 13 15 02 13 14 14 416 01 14 15 15 17 00 15 J5 T r T -Dii'ect- -Invei'sion Conversion- Reconversion It is proposed that the numerator of the fraction should be punched in the card, that is to say, in the case of rupees and annas, the amount would be punched in accordance with the usual notatiom. This is shown in the 'rst column of thetable. Listing, that is to say, the printing of the amounts entered'is eifected directly from the cards so that the amount actually punched printed as shown in the second column of the table. For 'adding purposes, the amounts are converted from the normal notation into the special notation appropriate to the adding mechanism. This notation involves halves of rupees i and eighths of halves of rupees and as shown in column 3, the numbers run from 00 to 0'1 and then from 10 to 17. "Subtracting'involves inverting the converted amounts as shown in column 4 of the table. This inversion gives the Ycomple- 'me'nt in the special notation of the amount entered, which, when added in, is' equivalent to In order that the total might be printed, it is necessary to reconvert the total standing in the adding mecha` nism back into the normal notation as shown by column 5 of the table.y

, Two special denominational adding sections are required for dealing with sixteenths and will be referred to as the units and the tens sections. The units section is arranged for an eighths notation and the gear ratio between the wheel I3 and the wheel 25 is 14 to 8 so that the addingwheel will make a complete revolutionfor an entry of eight. 'I'he units gear wheel I3 drives the corresponding wheel 50a through idler gears 54 so that the gear ratio betwee them is L6 to 14 and the units wheel 50a makes half a revolution for a revolution of the units wheel 21. The idler gear-ssa are provided in order that an the wheels 50 and 50a may be mountedo turn about the same axis in spite of the difference in gearratio. The tens gear wheel 26 and the tens4 wheel I3 havefa gear ratio of loto 14as 'in the case o1' the decimal wheels. and in the sameway the' tens wheel 5U and the tens wheel I3 have the gear ratio 20 to 14. The tens wheel is, however, arranged to transfer after every alternate step of movement, that is five times per revolution, and will thus read either 1 or 0. Thearrarfgement of the reading out commutators for the tens and units wheels will be explained later.

The conversion and the inversion of the annas -contacts 69 corresponding to the contacts 42,

39 and allocated tothe digits 0 and 1. The contacts 69 arey connected directly to commutator segments 10 which are read by a brush 1I at the 0 and 1 time in the cycle andl which are crossconnected to a second pair of segments 12 which arealso read at the 0 and 1 time by `a brush 13. 'I'he contacts 69 are also connected to a common 'segment 14 read by a brush 15 which is connected to the une I9.

If the left-hand, that is the 0, segment 69 is.

closed, a circuit will be established to the brush 1I at the 0 time and to the brush 13 at the 1 time. The brushes 1| and 13 are connected by contacts 22a and 22b respectively of the relay 22 to the tens adding magnet I6 so that if the amount being read .is to be added; an impulse willbe transmitted through the brush 1 I while if it is to be subtracted an impulse will be transmitted through the brush 13. The impulse through the brush 13 represents the complement of the digit represented by the impulse through the brush A1 I. Referring to columns 1 and 3 of the table given above it will be noted that 1 must be entered whenever the tens digit is 1 and that 0 is to be entered when the tens digit is (l unless the units digit is 8 or 9 when 1 has to be entered instead of 0. In order to enter 1 instead of 0 when the 8 or 9 is read in the units column of the annas rfield, the upper brush UBI that reads-this field is connected through cam contacts CF4 to a relay coil 16 and' a relay .11, The cam contacts CF4 operate during cardfeeding cycles and are normally open but close while the 8 and 9 positions on the card are .being read. Thus, ifthe brush UBI encounters an 8 or 9 hole a circuit will be set up -through this brush, the contacts CF4 and the coils'16 and 11.

cuit through cam contact CF5 and the contacts 16a and coils 16 and 11. The coil 11 when thus energized disengages the contacts 65 4and 66 and engages the contact 66 with the contact 18, thereby connecting the tens translator magnet 68 in series with cam contacts CF1 and'cam contacts CF8, these cam contacts being in parallel with one another. The cam contacts CF1 are arranged to close at the eight time in the cycle so that the translator magnet 68 will be energized in this time and will close the pair of con- ,tacts 69ay whose function will be explained later.

This circuit is immediately broken by the opening of the contacts 61 and the trip lever 34 is relatched against the armature of the magnet 68 by the movement of the trip pawl which it has just engaged.

The translator is thus in condition for a second [set-up. This set-up is effected by the contacts CF8 which close at theone time in the cycle l The coil 16 closesi its contacts 16a and establishes a holding cirbrush UBI through the units translator contacts 80. The units translator -is provided with tens contacts 8| one for each digit in the normal notation, one of which is closed in accordance with the units digit read. The contacts 8| are con- 5 nected on one side to a common segment 82 cooperating with a brush 99 which is connected to the line I 9'. The contacts 8l corresponding to the digits 0 to 7 are connected each to a commutator segment 83, there'being eight segments 83one 10 for each digit in the denomination appropriate to `the adding mechanism. The segments'83 are normally spaced so that they may be read by a. normally positioned brush 84 at the tmes.cor

responding to the digits 0 to 7. Thus, if the con- 15 tacts 8l allocated to the digit 4 are closed, the connected segment 83 will be engaged at the brush 84 by the four time in the cycle. 'I'he contacts for the digit 8 are cross-connected to the segment 83 for the digit 0 and the contacts 8| 20 for the digit 9 aresixnilarly connected to the seg'- i ment 83 for the digit 1. The segments 83 are each cross-connected to a segment 8.5 so that the v reading obtained` from the segments 85 by a normally positioned brush 86- will be the complement 25 of that obtained from the segments 83' by the brush 84. Referring now to the table, it will be noted that the set-up effected by closing one of the contacts 8| will render alive the contact spot corresponding toI the converted units digit as 30 shown by column 3 lof the table when the digit of the amount read is zero.

When the tens digit is 1 it is necessary to enter to the adding mechanism a digit which is twoy tens higher than the units digit read, that is to say,

the cycleof the adding mechanism. For this purpose a second brush 81 is provided two steps in advance o'f the brush 84. This brush will read each segment 83 `two steps earlier than the brush 84. That is to say, it will read the three segment 83 at the five time in the cycle so that ii' 45 the three segment is rendered alive by the closure of the contacts 8| for the digit 3, an impulse will be transmitted through brush 81 at the ve time in' the cycle. The three segment is connected to the four segment 85 since the com- 50 plement of three with respectto '7 is 4. It isl however, necessary to read two instead of four when the tens digit read is 1. That is to say, the segments 85. must be read two steps later in the cycle when the tens digit is 1 and ay special brush 88 is 55 provided; for this purpose.

The brushes 84 and 81 are connected to the contacts 22a"by triple contacts 89a of which the lower contacts are normally closed while the brushes 86 and 88 are connected to contact 22h by 400 triple contacts 89h of which the lower contacts are normally closed. It will be seen that the conf f 1 by the closure of the contacts 69 for the digit 1,

the segment 92 will be alive and :a circuit will be established through this segment, the brush 88 and the coil 89 during the whole of the following card cycle.` v

then operate two steps out of phase with the4 adding mechanism. From the table given above,

it will be noted that the tens translator will be set up to represent 1 when the units translator is set up to represent 8 or 9 and that in these two cases no phase change is required. As has been previously explained the contacts 69a of the tens translator are closed whenever 8 or 9 is read from the units column of the annas eld.

f A circuit is then established through the contacts 69a to a segment 9| and a brush 93, this circuit being in parallel with the circuit through magnet 89. This magnet is thus shunted by a path of low resistance and will not be energized so that the contacts 89a. `and 89h will remain in their normal position and no phase change will occur. Whether the amounts entered are to be added or. subtracted is determined by the contacts 22a. and 22h in the manner previously explained.

l In order to permitMof printing of the annas amounts directly from the cards, the lower brushes LBI and LB2 are plugged directly to the printing magnets controlling the type .bars by which the annas are to be printed. These two lower bushes are not, however, connected to any of the magnets I6.

It will be noted that the complementary amounts are obtained bycomplementing the units digit with respect to 7, the tens digit with respect to 1, and the remaining decimal digits with respect to 9. The complement thus obtained is one less than the tens complement which must be entered and an additional unit must be added on to theunits adding wheelswof the accumulator. This may be effected in any `known manner, for example, as is described in British patent specication 311,321, it may be entered into the units adding wheel from its transfer mechanism whenever the fX hole that denotes that an amount is negative-is read by the brush UB4.

Total printing-Sixteenths l Referring to Figs. 4 and 5,vthe units wheel 50 carries two pairs of brushes' |00 and |0|, the

two pairs being insulated yfromone another by a second insulating disk |02. The brushes |00 col impulse emitters and ||2 (see Fig. 3) which are identical with the emitter 58. The .segments 6| for the digits 0 to 7 of the emitter I2 are connected to the segments |04 like to like. The segments 6| for the digits 0 to 5 to the emitter are connected to the segments |04 fort-he digits 2 to'7 respectivelywhile the segment 6| of the digit 8 is connected to the segment |04 for the .digit 0 and the segment 6| of the digit 9 is connected to the segment |04 for the digit 1. The common seg` ment 59 of one emitter |2 is normally connected through contacts ||3a andv cam contacts R3 to .the line I 1, while the common segment |03 is con- .nected through a line 2| 4 to the printing magnet for printing the units denomination of the total. Thus as the emitt r ||2 operates during total printing cycle an i ulse will be transmitted'froin the line ,I1 through the contacts R3, ||3a, the emitter ||2, one of the segments |04, the brush |00, the 'segment' |03, the line 2|4 and the print magnet 29 to theL line 25. This impulse will pass at the' time determined by the position of the brush |00 and will result in the digit represented by the position of the brush |00 being printed.l

The circuit just described is completed whenever the tens adding wheel stands at 0. It will be seen from the table given above that when the tens adding wheel stands at |0, the digit to be printed is not. the digit standing on the units wheel, but the digit two units less. AReferring to Fig. 3, all of the segments |09 allocated to the digit= 1 are connected together and to a relay coil ||3 so that when cam contacts R2 c lose during total printing cycles, at circuit will be established through these contacts, the segments |08, ,the brush ||0, one of the segments |09 for the digit 1 and the coil ||3, if the brushris in position to represent 1. The coil |3 when thus energized opens the contacts ||3a and closes the contacts |3b, thereby interrupting the circuit through the emitter ||2 and completing the circuit through the emitter Owing to themanner in which the emitter is connected to the segments |04, the impulse which passes through the segment I 04 4which is engaged by the brush |00 will be transmitted two steps later in the cycle than if the emitter ||2 had been controlling the operation and the printing mag-net 29`will arrest its type bar in position to print a digit'two units lower than the digit standing cn the units adding wheel.

The energization of the magnet I3 also established a circuit from the line through the cam contacts R3, the contacts ||3b, cam contacts \R4 which close at the one time in the cycle, normally closed relay contacts |4a, a line ||5 and the lprinting magnet 29 allocated to -the tens denomination to the other supply line 25. The magnet will thus be energized to print 1. From the table given above it will be noted that 0 should be printed by the tens type bar when the tens adding wheel stands at and the units wheel stands at 1 or 0. When thisoccurs, the magnet |'I4 is energized and opens the relay contacts ||4a so that no circuitwill be established through the printing magnet 29. i

'I'he magnet is energizedover a circuit extending throgh th contacts R2, the segment |08, the brush 0, one of the segments 09 allocated to the digi't 1, the segment |05 of the second units commutator, the brush |0| and one of the segments |06 which are connected together and the magnet 4 to the line 25. This circuit can only be established under the conditions 4explained n above so that unless. both the tens adding wheel stands at l and the units Iadding wheel stands at `1 or 0 'they magnet ||4 will not be energized and the contacts ||4a will be closed. If the tens adding wheel stands at 0 the circuitl through the coil ||3 will be interrupted at the brush ||0 and the contacts ||3b will be lopened so that the circuit through the tens printing magnet will not be completed. Thus, if the tens adding-wheel stands at 0, or the tens adding wheel stands at 1 and the units adding wheel stands at Tor .0, the tens printing magnet will not be energized and the tens' type bar will rise ina known manner into position to print zero. f

It will be seen that one translating mechanism is used for converting the annas from a normalbe employed. The tons will be handled by denotation into a notation appropriate to the adding mechanism, while the second translating mechanism is employed for converting the totals back into the `normal notation. Both the translating mechanisms are operable either in phase with' the receiving device or two steps out of phase.

` ters and 2 of Fig. 3. In handling the tens 4Q necessary to enter 1 into thetens adding wheel' f digits advantage has been taken of the fact that the tens digits must be either 1 or 0 and the method in which the tens digits are handled as explained above is onlyapplicable to the fractions twelfths, fourteenths, sixteenths and eighteenths. Fractions such as fifteenths and those whose denominators are higher than 20 cannot be dealt with in the manner .just explained but must be handled 'in the manner which will be explained later. i

British currency f In British currencythe shillings are usually dealt with by employing a twos wheel for the ltens of shillings and the decimal wheel for the units of shillings. Hitherto, it has been the practice to employ a duo-decimal wheel for the pence which necessitates employing a duo-decimal type bar for printing the pence with the result that pence can only'be printed by a particular type bar so that Athe iiexibility of the machine is restricted. l

The mechanism just described 'may be modiiied in the following manner in order to deall The units adding wheel would with the pence. be ,a sixes Wheel and the amounts would be entered 'in a notation involving halves of shillings and sixths of halves of shillings. vSince it is when the units amount read is 6, '7, 8 or 9, the cam contacts CF1 (Fig. 2) are arranged to/close while the hole positions 9 to 6 are -being read.

The contacts 69a would be'thus allocated to the digit 6. The segments 83 and 85 for the digits 6 and 'l would be omitted and the contacts 8| for the digit 6 would be connectedto the segment 83 for the digit 0 the contacts 8| for the digit 7 to the segment 83 for the digit 0, and so on4 with contacts 8| for the digits 8 andV 9. It,y is necessary to have a phase change of four instead of a phase change of two and the brush 81 would therefore be situated .four steps in ad-- A vance of the brush 84 and the brush 88 four 1 ments 6| .of the commutator for the digits and 1 would be connected to the segments |04 for the digits 4 and 5 while the segments 6| for the digits 6, 7, 8 and 9 of thecommutator would be connected respectively to the segments |04 for the digits 0, 1, 2 and3.

, The operation of the mechanism with these modications is similar to that described above v and needs no further explanation.

'Ihe arrangement illustrated in Figs.v2 and 3 ls applicable to, weights involving pounds and ounces only. When, however, it is necessary to handle Weights involving tons, cwts., qrs. and lbs.

the mechanism illustrated in Figs.'8 and 9 must cimal wheels in the usual manner,the cwts. by means of a twos wheel and a decimal-wheel in the manner explained for shillings. The qrs.

`will be handled with a fours wheel in known manner. The lbs. are handled by a fours ywheel and a sevens wheel in the manner which will now be explained. In this present example, the long quarter is being considered. Its equivalent is twenty-eight pounds.

`Table II-Twenty-ez'ghths Punching Adding pgg'gg 04 04 04 05 05 05 06 06 06 07 08 11 08 09 12 09 10 13 10 11 14 11 12 15 12 13 16 13 14 20 14 15 21 15 16 22 16 17 23 17 18 24 18 19 y 25 19 20 y 26 20 21 30 21 22 v31 22 23 32 23 24 33 24 25 34 l 25 26 35 26 27 se f 27 Conversior] Reconversion` The above table shows the manner in which ytwenty-eighths are dealt with. The amounts are punched in the usual manner and are then converted into a Vspecial 'notation and subsequently the total is reconverted into the normal notation. The column of the card containing f Thus, there is a'double set up of the tens digit read.Y The units 'of lbs. are read by a brush UBI and a circuit is set up in a similar manner through lcontacts |24 and- |26, a translator magnet |25 and a translator magnet |21. The magnets |25 and |21 each control a separate translator so that there is a dual set-up of the units digit read. The four translators are shown one vbelow the yother in Fig. 9, the uppermost one being controlled bythe magnet 2|, the second by the magnet |23, the third by the magnet |25 kand the fourth by the magnet |21.

The uppermost translator comprises three contacts |28 connected at one side to a vcommon segment |29 which Iis read by a brush |30 and at the other side individuallyI eachto one of three segments |3|, |32, |33. These segments.

cooperate with brushes |34, |35 and |36 re- These brushes are connected respectively to one side of three magnets |31, |38 and |39 which are connected together to the other side and to the supply line 25 by a line |40. One of the contacts |28 will be closed in accordance with tens digit read so that during the following cycle a circuit will be established from the supply line I1 to the contacts CFI and LCLC, the line I9, the brush |30, the segment |29, the closed contacts |28, the connected segment/ISI and |32 or |33, and one-of the magnets |31, |38 and |39 to the line 25. One of these three magnets will thus be energized and will close contacts to control the operation of the units translating mechanism. The uppermost translating mechanism is thus purely a `controlling mechanism and does not emit timed impulses.

'I'helowermost translator comprises ten contacts 4| controlled rby the magnet |21 and connected at one side to a common segment |42 which cooperates with a'brush |43. The translator includes three commutators |44, |45 and |46 cooperating `respectively with brushes |41, |48 and |49 and each having seven segments whichpass the `cooperating brushes at the times 6 to 0 of the machine cycle, so that each segment corresponds to a digit of the notation of the units adding wheel. The contacts |4| for the digits 0 to 6 are each connected to the segment |44 for the same digit while the contacts |4| for the digits 7, 8 and 9 are connected respectively to the segments |44 for the digits 0, 1 and 2.

When the' tens digit is 0 the contacts |28 allocated to will be closed during one card cycle a'nd they will remain closed during the next cycle. The magnet |39 is thus energized during thislatter cycle and closes its contacts |3911 to connect the brush`|41 to the units adding magnet I6. An

d impulse will thus be transmitted to this magnet 44 and |45. The segments |45 are in turn connected each to the segments |46 for-the fourth higher digit that to 0 to 4,. 1 to 5, 2 to 6, 3 to 0, 4 to 1, etc. plus three between the commutators, |46 and |45. When the tens digit read is `1 the magnet |38 is energized and closes its contacts |38a, connecting the brush |49 to the units adding magnet' I6.

When the tens digit is 2 the magnet .|31 is enerf gized and closes its contacts I31a to connect the brush |48 to the units adding magnet I6. v

. Assume 4that thev units digit is 1 or 8. In either case the segment |44 for the digit 1, the segment |45 for the digit- 0 and the segment |46 for the digit 4 will be connected to the common segment |42. Whether 1,'0or 4 is added depends on the tens digit read. If the tens digit is 0, 1 is 'added and it will' be noted from Table II that when both 01 and 08are read, 1 is to be added in the units wheel While if the tens digit is 1, 4 will be aded and from Table II it will be seen that when .'11 or 18 is read, 4 must be added into the units wheel. In the same way when 21 is read, 0 will be added into the units wheel. The outer units translator controls the operation of the second tens-translator. This units translator comprises contacts |50 controlled by the magnet |25 and connected on one side to a common segment |I which cooperates with a brush |52. On their other sides the contacts are connected as shown There is thus a phase difference of in groups to segments |53, |54 and |55 which cooperate with brushes |51, I 58 and |59. the contacts |50 for the digits 7, 8 or 9 are closed during one card cycle, a circuit will be established; extending through the brush |52, the segment |5I, the closed contacts |50 the segment |53, the brush |51 and the relay magnet ISI-which will be energized for the duration of thev succeeding card cycle. In the same way the magnet |62 is energized if the units digit read is 4, 5, or 6, the magnet |63 if this digit is 1, 2 or 3.

The second tens translator` comprises' three contacts |65 controlled by the magnet |23 and allocated to the digits 0, '1 and 2. The contacts |68 are connected to a common segment |66 cooperating with a brush I 61 and individually to segment |68 allocated to the digits 0, 1 and 2 and cooperating with a vbrush |12 which is connected to th tens adding magnet I6. Thus when one of contacts |65 has been closed in accordance with the tens digit read, an impulse will be transmitted through the closed contacts |65, the connected segment |68, the brush |12 andthe tens adding magnet at the time in the cycle corresponding to the digit read.

`It will be seen from Table II that the digit entered must in certain cases be one more than the digit read. That is, a phase change of 1 is required. The translator is provided with segments I69,'|10 and |1J allocated respectively to the digF its 1, 2 and 3 and connected each to the segment |68 -for the next lower digit. The segments |69 and and I1I cooperate with brushes |13, |14 and which may be connected to the tens adding magnets I6 bythe closure of normally open contacts |6|a to |63a controlled by the magnets |6| to |63. i

If the units digit entered is 7, 8 or 9, a phase change must always be eiected as may be seen from Table II. 'When one of these digits is entered, the magnet I6| is energized as explained above and closes the contacts I6Ia, |6|b and,`

|6|c, which connect all lthree brushes |13, |14 and |15 to the entering magnet. Then a circuit will be established through the closed contacts |65, the connected segments |68 and |69, |10 or I'1I, the cooperating brush |13, |14 or |15, the contacts |6Ia, I6Ib, or I6 Ic and'the tens adding magnet I6 and contacts 24. The tens adding vmagnet then engages its clutch at the time corresponding to the digit that is one higher than the digit read and opens its contacts 24, in a known manner, to break the tens adding circuit. Immediately after this, the brush |12 engages the segment |60 that is connected to the closed contacts |65 but no circuit is completed since the contacts 24 are open. v.

If the units digit read is 4, `5, or 6, a lphase change must 'be effected when the tens digit is 1v or 2- butvnot when it is 0.. The magnet |62 is energized when the units digit is 4, 5, or 6 and closescontacts I62a and |62b to Jconnect the brushes |14 and |15 to the entering magnet. If the tens digit is 1 or 2, a circuit is established, as explained above, through the segment |10 or the segment I1| at the 2 or the 3 time in the cycle, but, if the tens digit is 0, no circuit will be established through the-segment |69 at the "1 time since the contacts IBI-a are open and the brush |13l is not connected to the tens adding magnet.

`Thusif the tens digit is 0 the tens adding magnet will be energized at the 0 time through the |63 is energized and closes the contacts |63a so that the brush I 15 is connected to the tens adding magnet but not the brushes |13 and |14. The tens adding magnet will now be energized at the 3 time if the contacts |65 for the digit 2 are closed, and at the 1 or the 0 time if the contacts allocated |65 to 1 or 0 are closed.

Total priniing-twenty-eigmhs The units adding-section of the accumulator is provided with three reading out commutators |80,

pair of brushes and four insulated segments.v

'I'he machine is provided with a single emitting or timing commutator |85 similar to the commutator 58 and driven by thc reset motor, whose common segment 59 is connected to the main line |1 and whose segments 6| are connected individually to bus lines |86. be connected to the decimal reading out commutators in the manner` explained. The segments |81 of the commutator |80 are connected individually to bus lines |88 while the common segment |90 of this commutator is connected to the units printing magnet 29. Thus one `of the bus lines |88 will be connected to the magnet 29 by the brush |90 in accordance with the units digit of the total on the accumulator. Each line |88 thus has a digital value and the lines |86 also have a digital value. Eachjof the lines |88 may be connected to the line |86 for the same digitl by the closure of a group of normally open contacts |9|a to I 9 Ig, to the line |88 for the third lower digit by the closure of a group of contacts |92a to |92g, to the line |86 for the fourth higher Value by the closure of a group of contacts |93a to |939 and to the line |86 for the nexthigher value by the closure of a group of contacts |94a to |94g.

The common segment A|95 of the commutator |84 is connected-through contacts R5 to the supply line |1 and the segments |96 are connected individually to relay magnets |9I, |92, |93 and |94.

Assume that the total on the accumulator is l2, in which case 9 is to be printed. When a reset cycle is initiated, the 4contacts R5 close just before the "9 time in the cycle and open just after the time. A circuit is thus established from the line I1 through the contacts R5, the segment |95, the brush |95 which stands at 1" the segment |96 for 1 and the relay magnet |92 to the line 25. The magnet |92 then closes the relay contacts |92a to |92g. The brush 60 of the emitting commutator |85 is rotating and when it reaches the "9 segment a circuit is established extending from the line |1 through the segment 59, the brush 60, the segment 6| for "9 the line |86 for 9, the

' contacts |92e, the third line |88 tothe left, the

- segmenty |81 for 2, the brush |90, the segment The common segment |98 of the tens reading out commutator. |83 is connected to themagnet 29. Since O is to be printed when the tens digit .of the total is 0 and 2 when the tens digit is 3 (see Table l1) the segments |99 for 0 and 3 are connected to the bus lines 86 which transmit im- The bus lines |35 may .tablished at the 1 time in the cycle.

pulses at the 0 and 2 times respectively. The i segment |99 for 1 is connected to the common segment 20| of the units reading out commutator |82'Whose segments 202 forfO, 1 and 2 are connected to the line |86 transmitting at the "0 'time and whose segments 202 for "3 to "6 are connected to the line |86 transmitting at the 1 time. The segment |99 for 2 is connected to the common segment 234 of the units commutator whose segments 205 for "0 to "5 are connected to the line |86 transmitting at the "1 time whose segment 205 for 6 is connected to the line |86 transmitting at the 2 time.

Taking the example of 12 considered above, the brushes 20| and 206 willengage the segments for 2 and the brush 200 the segment for 1. When the brush 60 reaches the segment 6| for 0 a circuit will be established through the left hand. line |86, the segment 202 for 2, the brush 203, the common segment 20|, the segment |99 for 1, the brush 20|), the common segment |98 and the tens magnet 29. This magnet will thus be energized at the zero time and will arrest its type bar in position to print zero. If the digit had been 3, 4, 5, or 6, a circuit would have been es- When the tens digit is 2 the circuit extends through the commutator |8| and 4is established at the 2 time if the units digit is 6, and at the 1 time for the other units digits.

The above has described how twenty-eighths may be added and the total printed. Subtraction may be effected in a mannery analogous to that described with reference to Fig. 2.

It will be seen that the controlling record cards may be punched in the normal manner so that the amounts may be printed directly from the cards in the normal notation. The amounts read are converted into a special notation for add-l ing purposes and the total reconverted into the normal notation for printing. The translating f mechanism shown in Figs. 2 and 6 is applicable only to machines in which the cards are read in.

motion. When the invention is applied t'o a record card controlled machine in which the cards are read while stationary by a pin box mechanism or to a machine in which the amounts are entered by a keyboard, the translatingfmechanism for converting the amounts read or entered and transmitting them to the adding mechanism would be arranged in the manner shown in' Fig. 9 Where there is a stationary set up of the amount to be converted. It will be noted that no number higher than nine has to be printed by any type to a machine. having but one accumulator but can readily be applied to one-having several accumulators, it beingmerely necessary to provide a suilicient number f-special adding sections and translators. As stated above, the transfer mechanism is preferably of the electrical kind. The use of electrical transfer mechanism is preferred since it is then merely necessary to provide a suitable number of special adding sections, say, in the case tof sixteenths, five ftwos and ve eights adding sections. These special sections can then be plugged up through\t\he transfer mechanism to the decimal adding sections to form complete accumulators.

It will be appreciated that the invention is not restricted in its application to statistical machines but is also applicable to adding and other calculating machines,

Having now particularly described and ascertained the nature of the said invention and in What manner the same is to be performed, I intend to be limited only by the scope of the fol- -lowing claims. v

I claim:-

1. In a machinefor handling fractions, means for analyzing a perforation in a column of' a record card representing by its location the numerator of a fraction, an 'entry receiving mechanism including a plurality of devices advanceable in different increments and having transfer mechanism between the individual devices, entering means therefor and means controlled by said analyzing means upon analysis of said perfora- 4 tion for causing operation of said entering means andan advance of each of vsaid devices by amounts jointly indicative of the value of. said fraction.

2. In a machine for handling fractions, means for analyzing a perforation infa column of a' for' analyzing a record card for perforations representative of the numerator of a fraction, means -controlled by said analyzing means for ebnverting the numerator analyzed, into numerators of a plurality of other fractions of different denominations, adding mechanism including a' pair of denominational ordersv with transfer vmechanism therebetween, entering means therefor adapted toreceive numerators of said last named fractions and means controlled by said converting means for causing operation of said entering means and an advance of each of said pair of denominational orders by amounts jointly indicative. of the value of said fraction.

4. In a machine of the class described, means for analyzing perforationsin a record card representative of annas, an accumulator including a denominational order adapted to receive entries in increments representative of sixteenths of a rupee and a denominational ordervadapted to receive entries in increments representative of half a rupee, and means controlled by said analyzing means for converting annas into halves of rupees and s-ixteenths of a rupee and for causing the entry of the even halves of a rupee in the second named order and the remainder in the first named order.

5. In a machine of the class described, means. for analyzing a pair of columns of a record card for perforations representing tens of annas in one column and units of annas in the other, an ac-' cumulatorl including a denominational order adapted to receive entries in increments representative of sixteenths of a rupee and a denomi-4 national order adapted to receive entries in increments representative of half a rupee, and means controlled by said analyzing means for converting-the tens and units of annas;I into halves of rupees and sixteenths of rupees and for causing the entry of the even halves of a rupee in the second named order and the remainder in the rst named order.

6. In a machine of the class described, mean for analyzing a pair of columns "of a record card for perforations representing tens of pounds in one column and units vof pounds in the other, an accumulatcr including a denominational order adapted to receive entries in increments representativeof sevenths of a quarter and a denominational order adapted to receive entries in increments representative of fourths of a quarter, and means controlled by said analyzing means for converting the tens and units of columns into quarters and sevenths of quarters and for causing the entry of even thirds of a quarter in the second 'named order and the remainder in'the rst named order.

CHARLES CAMPBELL. 

